KR20110055664A - Pressure regulator - Google Patents

Abstract

The communication hole 17 communicating the primary port 15 and the secondary port 16 is opened and closed by a valve element 21 in contact with the valve seat 18, and a valve seat 18 is provided in the valve element 21. The spring force in the direction of contacting) is exerted by the valve spring 25. A pressure regulating diaphragm 27 is mounted to the housing 11 opposite the valve element 21, and the pressure regulating diaphragm 27 is a spring in a direction in which the valve element 21 is opened by a pressure regulating spring 43. Power is given. A stem 46 having a tip face 49 for opening and closing the relief ball 37 and transmitting a movement of the pressure regulating diaphragm 27 toward the valve element 21 to the valve element 21 is provided with a valve element 21. It is installed in). The pressure regulation diaphragm 27 suppresses the vibration of the pressure regulation diaphragm 27 at the time of exhausting from the relief ball 37, and at the time of pressure regulation, the pressure regulation diaphragm 27 of the valve assembly 26 together with the diaphragm assembly 38. A dynamic vibration absorber 50 for suppressing vibration is provided.

Description

Pressure Regulator

The present invention relates to a pressure regulator for supplying a fluid pressure actuator by adjusting the pressure fluid supplied from the fluid supply source to a predetermined pressure.

A pressure regulator is used to control the compressed air supplied from a pneumatic source, which is a fluid supply source, to a predetermined pressure, and to supply the pneumatic source to a pneumatic actuator such as a pneumatic cylinder. Such a pressure regulator includes, for example, a primary side port to which compressed air is supplied, and a secondary side port to which a pneumatic actuator is connected, as described in Patent Document 1, and is opened and closed by an opening end of a communication hole communicating therewith. A spring force is applied to the valve element in the direction of closing the valve seat by the valve spring. The pressure regulator includes a diaphragm elastically deformed by the differential pressure between the set pressure of the secondary side port and the atmospheric pressure, and the diaphragm has a relief ball for discharging the secondary air to the outside. The tip of the stem attached to the valve element is in contact with the diaphragm to close the relief ball, and the diaphragm is exerted with a spring force in the direction of opening the valve seat through the stem by means of a pressure regulating spring.

In such a pressure regulator, when the pressure on the secondary side is lower than the set pressure, the diaphragm opens the valve seat through the stem by the spring force of the pressure regulating spring, and the compressed air on the primary side is supplied to the secondary port. When the pressure of the compressed air of the secondary port reaches the set pressure, the diaphragm is displaced in a direction falling from the valve element due to the air pressure applied to the diaphragm so that the valve element contacts the valve seat and closes the valve seat. The communication of the secondary port is cut off.

On the other hand, when the secondary pressure rises above the set pressure, the diaphragm is displaced in a direction falling from the valve element, the diaphragm is separated from the tip of the stem, and the relief ball is opened to open the secondary pressure to the outside. When the secondary pressure drops, the diaphragm contacts the stem, causing the relief ball to close. Thus, for example, when the pressure used in the pneumatic circuit having the pneumatic actuator is lowered to decompress the compressed air supplied to the air, the secondary pressure is newly set low. As a result, the compressed air in the secondary pipe is exhausted to the outside through the relief ball up to the newly set set pressure. In addition, when the set pressure on the secondary side rises because a load in a direction opposite to the rod operating direction of the air trap cylinder or the like rises from the outside, the compressed air in the secondary pipe may be released to maintain the set pressure. Exhaust through the outside.

When the pressure of the compressed air supplied to the secondary port is set to intermittently draw a pneumatic actuator such as a pneumatic cylinder, the valve seat is frequently opened and closed by the valve element because the secondary air is consumed and the pressure fluctuates intermittently. Will be. Therefore, the valve element vibrates due to the intermittent flow of the compressed air flowing from the primary port to the secondary port. As the vibration noise is generated, the secondary pressure constantly fluctuates and the stability is lowered. On the other hand, when exhausting the air in the secondary pipe through the relief ball, the diaphragm vibrates due to the air flowing back from the secondary port to the relief ball, and the vibration pressure is generated and the secondary pressure constantly fluctuates, resulting in stability. Will be degraded. Vibration of the valve element and the diaphragm promotes wear of the seal-material installed on the valve element and also facilitates deterioration of the diaphragm, thereby degrading the durability of the pressure regulator. Moreover, the vibrations that occur at the same time worsen the working environment.

A dynamic vibration absorber is known as a vibration controller that suppresses vibration of a vibrating body. Dynamic vibration absorber is composed of mass body, spring, damper, and mass body is attached to the vibration control object through spring and damper. When the vibration control object vibrates, the mass body of the dynamic vibration absorber vibrates, a part of the vibration energy of the vibration control object is converted into the vibration energy of the mass body, and the vibration of the vibration control object is suppressed. Patent Document 2 describes a dynamic vibration absorber for absorbing vibrations of a substrate of an electric device, and Patent Document 3 describes a dynamic vibration absorber for suppressing vibrations generated by a power mechanism assembled to a microscope. The dynamic vibration absorber is called a dynamic vibration upserver or dynamic vibration reducer.

Patent Document 1: Japanese Patent Application Laid-Open No. 10-268943

Patent Document 2: Japanese Patent Application Laid-Open No. 2007-285320

Patent Document 3: Korean Patent No. 3911372

As described above, when the pressure of the compressed air supplied to the secondary side port is set to intermittently draw the pneumatic actuator such as the pneumatic cylinder, the valve seat is closed by the valve element because the secondary air is consumed and the pressure also fluctuates intermittently. Is frequently opened and closed. When the frequency of the compressed air pulsating from the primary port to the secondary port coincides with the natural frequency of the movable part including the valve element, the valve element resonates. When the valve element vibrates, the opening of the valve seat does not become a predetermined opening degree corresponding to the set pressure on the secondary side, so that the secondary pressure fluctuates, and the pressure regulating stability of the pressure regulator is lowered. On the other hand, when exhausting the air in the secondary pipe through the relief ball, the diaphragm vibrates due to the flow of air flowing back from the secondary port to the relief ball, and the secondary pressure fluctuates so as to deviate from the set pressure and stabilize the pressure regulator of the pressure regulator. This will fall. Moreover, the vibrations that occur at the same time worsen the working environment.

Therefore, in the conventional pressure regulator, in order to avoid the resonance phenomenon when the valve element opens and closes the valve seat to adjust the pressure, sliding resistance such as an O-ring attached to the valve element or the stem is reduced. It was necessary to design with a damping element. On the other hand, in order to avoid the resonance phenomenon of the diaphragm when opening the relief ball to exhaust the secondary side air, the method of reducing the diaphragm's operability by increasing the diaphragm elasticity, or using a rubber material as a damping element The method of adhering to a sheet | seat or a stem, etc. are employ | adopted. In this way, the attenuation elements are provided in the valve element diaphragms, respectively, to impede the opening and closing movement of the valve element and significantly impair the pressure regulating response performance of the pressure regulator.

In the pressure regulator, as described above, the vibration system is different from the pressure regulation at which the valve element operates and the exhaust time to exhaust air from the secondary port to the outside. That is, the vibration system of the valve element vibrates at the time of pressure regulation, and the vibration system of the diaphragm vibrates because the diaphragm falls from the valve element at the time of exhaust. In order to suppress the vibration of these vibration systems by the dynamic vibration absorber, it is necessary to equip each vibration system with a dynamic vibration absorber, and it is quite difficult to mount a plurality of dynamic vibration absorbers in a limited space. In addition, an air flow path is formed in the pressure regulator, and the installation of the dynamic vibration absorber at a portion that does not impede the flow of air degrades the pressure regulating characteristics.

An object of the present invention is to improve the pressure regulation stability of the pressure regulator.

An object of the present invention is to increase the pressure regulation stability of the pressure regulator by suppressing the vibration of the valve element and the diaphragm without impeding the flow of air.

An object of the present invention is to suppress the occurrence of vibration of the valve element and the diaphragm to improve the durability of the pressure regulator.

The pressure regulator of the present invention includes a housing having a primary side port through which a pressure fluid is supplied and a secondary side port communicating with a primary side port through a communication hole and outflowing the pressure fluid, and a valve seat formed at an opening end side of the communication hole. A valve assembly having a valve element for opening and closing the valve element, and a valve spring for imparting a spring force in a direction of closing the valve seat with respect to the valve element, and a pressure regulating chamber mounted to the housing opposite the valve element and in communication with the secondary port. A pressure regulating diaphragm for partitioning the spring chamber communicating with the valve and a retainer installed in the pressure regulating diaphragm and a spring receiving member disposed in the spring chamber opposite to the retainer to open the valve element in the valve seat. A diaphragm assembly having a pressure regulating spring for imparting spring force to the valve element; It has a front end surface which is formed in you and opens and closes the relief ball which communicates the pressure regulating chamber and the spring chamber. And to suppress vibration of the diaphragm assembly when the diaphragm is away from the stem, and vibration of the diaphragm assembly and the valve assembly when the valve assembly adjusts the pressure of the secondary port while opening and closing the valve seat with the diaphragm assembly. It characterized in that it comprises a dynamic vibration absorber to suppress the.

In the pressure regulator of the present invention, the dynamic vibration absorber is provided between an annular damper fixed to the tip of a supporting rod protruding from the retainer toward the spring receiving member, an annular mass body installed on the annular damper, and between the diaphragm and the annular mass body. And a spring member to be mounted. In the pressure regulator of the present invention, the retainer has a disk portion provided with a supporting rod and abuts on the diaphragm, and a dynamic vibration absorber is provided at the tip of the supporting rod inside the pressure regulating spring mounted between the disk portion and the spring receiving member. Characterized in that the mounting position. The pressure regulator of the present invention is such that the natural frequency of the dynamic vibration absorber is different from the natural frequency of the diaphragm vibration system constituted by the diaphragm assembly and the complex natural frequency of the complex vibration system composed of the valve assembly and the diaphragm assembly. It features.

The pressure regulator of the present invention is characterized by providing a seal member at the distal end of the stem that seals the communication between the pressure control chamber and the secondary port communicating through a through hole that slidably supports the distal end of the stem. It features. The pressure regulator of the present invention is characterized in that a diaphragm for movably supporting the stem in the opening and closing direction of the relief ball and sealing the communication between the secondary port and the pressure regulating chamber is provided at the tip of the stem. The pressure regulator of the present invention is characterized in that it further comprises a pressure balance seal member for sealing between the valve element and the guide ball in which the valve element is assembled. The pressure regulator of the present invention is further characterized by a pressure balance diaphragm which seals between the valve element and a guide ball into which the valve element is assembled.

According to the present invention, when the valve element is opened and closed to adjust the pressure of air supplied to the secondary port, the vibration of the valve assembly and the diaphragm assembly is prevented by the dynamic vibration absorber mounted on the diaphragm assembly. . At the time of exhausting the compressed air of the secondary port to the outside through the relief ball, the vibration of the diaphragm assembly is suppressed by the dynamic vibration absorber mounted on the diaphragm assembly. This makes it possible to increase the pressure regulation stability of the compressed air supplied to the secondary port.

Since it is possible to suppress the occurrence of vibration of the valve assembly and the diaphragm assembly, it is possible to improve the durability of the pressure regulating valve. At the same time, it is possible to improve the working environment by suppressing the generation of vibration sound.

It is possible to prevent the synchronized vibration of the exhaust body and the diaphragm assembly by the dynamic vibration absorber, and also to suppress the vibration of the diaphragm assembly. It is possible to suppress the generation of vibration at the time of operation.

Since the dynamic vibration absorber is assembled inside the pressure regulating spring of the diaphragm assembly, the dynamic vibration absorber is prevented from inhibiting the flow of air in the pressure regulating valve without increasing the pressure regulating valve.

1 is a cross-sectional view of a pressure regulator according to an embodiment of the present invention.
Figure 2a is a cross-sectional view showing the valve assembly and the diaphragm assembly at the time of pressure regulation, Figure 2b is a cross-sectional view showing the valve assembly and the diaphragm assembly at the time of exhaust.
3A is a vibration model of the combined vibration system 46 at the time of pressure regulation, and 3B is a vibration model of the diaphragm vibration system 46 at the time of exhaust.
4 is a cross-sectional view showing a pressure regulating valve according to another embodiment of the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail based on drawing. As shown in FIG. 1, the pressure regulator has a housing 11, which is opposed to the housing body 12, the cap 13 attached thereto, and the cap 13. A bonnet 14 attached to the housing main body 12. The housing main body 12 has a primary side port 15 communicating with a compressed air source as a fluid pressure source, and a secondary side port 16 communicating with a pneumatic actuator as a fluid pressure actuator, such as a pneumatic cylinder. It is formed coaxially as shown in FIG. Communication holes 17 communicating the primary port 15 and the secondary port 16 are formed in the housing body 12 in a direction perpendicular to the central axis of both ports 15 and 16. The communication hole 17 has an opening portion facing the cap 13, and a valve seat 18 is formed at the opening side of the communication hole 17 in the housing main body 12.

In the cap 13 a valve element 21 is mounted so as to be reciprocating in the axial direction, the valve element 21 being in contact with and closing the valve seat 18 and in the valve seat 18 It works by falling apart and opening it. The valve element 21 is integrally provided at the tip portion of the shaft portion 21a and the shaft portion 21a slidably fitted into the guide hole 22 formed in the cap 13 so as to face the valve seat 18. The flange part 21b is provided. A rubber seal member 23 is provided on the front surface of the flange portion 21b in contact with the valve seat 18. The shaft portion 21a has a pressure balance seal member that contacts the inner circumferential surface of the guide hole 22 and seals communication between the shaft portion 21a of the valve element 21 and the primary port 15 and the secondary port 16 ( 24) is installed. However, a pressure regulator of the type in which the seal member 24 is not provided in the shaft portion 21a of the valve element 21 may be used.

The cap 13 has a cylindrical attachment portion 13a provided with a male screw for screwing into a female screw formed in the housing main body 12, and a guide tube portion integrally formed with the cap 13 and having a guide hole 22 formed therein. (guide cylinder portion, 13b), and a compression coil spring is assembled as the valve spring 25 in the space between the mounting portion 13a and the guide cylinder portion 13b. One end surface of the valve spring 25 is in contact with the outer surface of the flange portion 21b of the valve element 21, and the other end surface is in contact with the inner surface of the cap 13, and the valve element 25 is formed by the valve spring 25. The spring force is applied to 21 in the direction of closing the valve seat 18. The valve element 21 and the valve spring 25 constitute the valve assembly 26.

The rubber pressure regulating diaphragm 27 is mounted in a sandwiched state by the housing main body 12 and the bonnet 14 screwed thereto, and the pressure regulating diaphragm 27 has a reinforcing disk 28. Is attached. The pressure regulation diaphragm 27 partitions the spring chamber 31 inside the bonnet 14 and the pressure regulation chamber 32 on the housing main body 12 side. An aspirator 33 made of a pipe member is attached to the housing body 12. The aspirator 33 has one end opening in the pressure regulating chamber 32, the other end opening in the secondary port 16, and the pressure regulating chamber 32 has a pilot ball ( 34 is communicated with the secondary port 16. The spring chamber 31 is communicated to the outside by a bleed port 35 formed in the bonnet 14, and the spring chamber 31 is brought to atmospheric pressure.

A retainer 36 is attached to the spring chamber 31 side of the pressure regulating diaphragm 27 via the reinforcing disk 28. The retainer 36 has a diskportion 36a which abuts against the pressure regulating diaphragm 27 via the reinforcing disk 28 and a support rod portion 36b protruding in the axial direction. Equipped. In the central axis of the pressure regulating diaphragm 27, the reinforcing disk 28, and the retainer 36, a relief ball 37 for communicating the pressure regulating chamber 32 and the spring chamber 31 is formed. do. The diaphragm assembly 38 is formed by the pressure regulating diaphragm 27, the reinforcing disk 28, the retainer 36 and the pressure regulating spring 43.

The bonnet 14 has a cylindrical portion 14b in which an end wall portion 14a is integrally formed, and at the opening end of the cylindrical portion 14b, a male screw is screwed into a female screw formed in the housing main body 12. Is formed, the bonnet 14 is configured to be screwed to the housing body (12). The adjustment spring shaft 39 is rotatably mounted to the end wall portion 14a, and the male screw of the adjustment spring shaft 39 is screwed to the spring receiving member 42 disposed in the spring chamber 31. . A compression coil spring is mounted as the pressure regulating spring 43 between the spring receiving member 42 and the disk portion 36a of the retainer 36 fixed to the pressure regulating diaphragm 27, and the pressure regulating spring 43 Is applied to the pressure regulating diaphragm 27 in the direction of opening the valve element 21 from the valve seat 18 toward the valve element 21. An operating handle 44 is attached to the adjustment spring shaft 39 to adjust the spring force. When the spring receiving member 42 is moved in the axial direction by rotating the adjustment spring shaft 39 through the operation handle 44, the amount of expansion and contraction of the pressure regulating spring 43 is adjusted. Thereby, the spring force applied to the pressure regulation diaphragm 27 is adjusted corresponding to the amount of expansion and contraction. The lock cover 45 is attached to the operation handle 44, and the operation handle 44 is operated by the lock cover 45. When the lock cover 45 is moved in the axial direction, the rotation of the operation handle 44 is prevented. Regulated.

The valve element 21 is attached with a stem 46 consisting of, for example, a metallic rod-like member, which stem 46 forms part of the valve assembly 26. The proximal end of the stem 46 is fitted and engaged in an attachment hole formed in the valve element 21, and the stem 46 is fixed to the valve element 21 by means of a securing portion formed in the proximal end. The tip end portion of the stem 46 passes through the through hole 47 formed in the housing main body 12, and the tip end face 49 is hemispherical. The front end of the stem 46 is attached with an O-ring 48 which moves in contact with the inner surface of the through hole 47, and the front end of the stem 46 is supported by the housing main body 12 to be attached to the O-ring 48. It seals between the communication hole 17 and the pressure regulation chamber 32 by this. The stem 46 is capable of reciprocating axially with the valve element 21, and the relief ball 37 closes when the hemispherical tip 49 of the stem 46 contacts the pressure regulating diaphragm 27. And the relief ball 37 is opened when the pressure regulation diaphragm 27 falls off the stem 46.

When the pressure of the secondary port 16 drops, the pressure of the pressure regulating chamber 32 is dropped by the pilot ball 34 of the aspirator 33 communicated with the pressure regulating chamber 32. As shown, the tip 49 of the stem 46 closes the relief ball 37. In this closed state, the valve element 21 is driven in the direction away from the valve seat 18 by the pressure regulating spring 43 via the pressure regulating diaphragm 27 and the stem 46. Becomes open. The opening degree of the valve element 21 at this time is changed corresponding to the pressure of the pressure regulating chamber 32, and the pressure of the secondary port 16 is adjusted to the set pressure. Therefore, when the pressure of the secondary side port 16 becomes a pressure lower than the pressure set by the spring force of the pressure regulation spring 43, the secondary side port 16 at the primary side port 15 via the communication hole 17. The compressed air flows into the secondary port 16 and the pressure of the compressed air is adjusted to a set value.

On the other hand, if the pressure of the compressed air supplied to the secondary side port 16 is higher than the set pressure, the valve element 21 abuts the valve seat 18 and as shown in FIG. 2B, the axial direction of the valve element 21. Movement is regulated. In this regulated state, the pressure regulating spring 43 contracts by the pressure of the pressure regulating chamber 32 so that the pressure regulating diaphragm 27 falls off the tip end 49 of the stem 46, and the relief ball 37 ) Is opened to an exhaust state. Therefore, when the pressure of the secondary side port 16 becomes a pressure higher than the pressure set by the spring force of the pressure regulating spring 43, the compressed air supplied to the secondary side port 16 is released from the pressure regulation chamber 32. The ball 37 is introduced into the spring chamber 31 and discharged from the bleed port 35, and the pressure of the compressed air supplied to the secondary port 16 is adjusted to a set value. For example, in the pneumatic circuit provided with the pneumatic actuator, when the pressure being used is lowered, when the compressed air supplied to the pneumatic actuator is depressurized, the pressure on the secondary side is newly set low. As a result, the compressed air of the secondary port 16 is exhausted to the outside through the relief ball 37 up to the newly set set pressure. In addition, when the set pressure on the secondary side rises due to the external load acting in a direction opposite to the rod operating direction of the pneumatic cylinder or the like, in order to keep the set pressure constant, the compressed air of the secondary port 16 is discharged to the relief ball. It is exhausted to the outside through 37.

The pressure regulator comprises a valve assembly 26 constituted by a valve element 21, a stem 46, and a valve spring 25, a pressure regulating diaphragm 27, a reinforcing disk 28, and a retainer 36. And a diaphragm assembly 38 constituted by a pressure regulating spring 43, each of which vibrates in response to a pressure situation in the flow path. Focusing on the vibration phenomenon, the valve assembly 26 constitutes the valve element vibration system 46 and the diaphragm assembly 38 constitutes the diaphragm vibration system 46. The air flowing from the primary side port 15 to the secondary side port 16 is operated because the valve assembly 26 and the diaphragm assembly 38 operate in synchronism when the valve element 21 opens and closes. When the frequency due to pulsation approaches the complex natural frequency of the complex vibration system 46 formed by the valve assembly 26 and the diaphragm assembly 38, vibration noise is generated by resonance and pressure control stability is lowered. Will be.

On the other hand, when exhausting the air in the secondary side port 16 to the outside from the relief ball 37, the valve assembly 26 is restricted by the valve element 21 abuts the valve seat 18, Since the diaphragm assembly 38 is operated away from the valve assembly 26, the frequency of the diaphragm assembly 38 due to the pulsation of air discharged to the outside through the relief ball 37 at the secondary port 16 is caused. Approaching the natural frequency of the diaphragm vibration system 46 formed by), the vibration sound is generated by the resonance and the pressure regulation stability is lowered.

The retainer 36 supporting rod portion 36b is equipped with a dynamic-vibration absorbing apparatus 50 to suppress each of the aforementioned vibrations. The dynamic vibration absorber 50 includes a coil spring 51 as a spring member, an annular damper 52 made of rubber as a damping member, and an annular weight member, that is, an annular mass body 53. do. One end surface of the annular damper 52 is fixed to the mounting plate 54 fixed to the front end of the supporting rod portion 36b, and the annular mass 53 is fixed to the other end surface. A coil spring 51 is mounted between the annular mass 53 and the disk portion 36a of the retainer 36.

The dynamic vibration absorber 50 is located in the inner space of the pressure regulating spring 43 mounted in the spring chamber 31 and assembled to the retainer 36. The support rod portion 36b of the retainer 36 is formed concentrically with the central axis of the pressure regulating diaphragm 27, and the dynamic vibration absorber 50 having a cylindrical shape as a whole is formed outside the support rod portion 36b. Is mounted. Since the dynamic vibration absorber 50 is disposed outside the support rod portion 36b, the flow of air flowing into the spring chamber 31 from the relief ball 37 inside the support rod portion 36b causes dynamic vibration. It is not disturbed by the absorber 50. In addition, since the dynamic vibration absorber 50 is mounted concentrically with the central axis of the support rod portion 36b, even if the valve element 21 and the pressure regulating diaphragm 27 move in the axial direction, No load is applied in the tilting direction.

3A is a vibration model of the combined vibration system at the time of pressure regulation, and 3B is a vibration model of the diaphragm vibration system at the time of exhaust. 3, m is the mass of the annular mass 53, c is the damping coefficient of the annular damper 52, k is the spring constant of the coil spring 51, and K1 is the spring constant of the pressure regulating spring 43. , K2 is the spring constant of the valve spring 25, M1 is the mass of the diaphragm assembly 38, M2 is the mass of the valve assembly 26.

If the natural frequency of the diaphragm vibration system is Ω1, the natural frequency of the valve element vibration system is Ω2, and the complex natural frequency of both vibration systems is Ωc, the natural frequency ω of the dynamic vibration absorber 50 is the natural frequency Ω1. Different from the complex natural frequency? C.

As shown in FIG. 2A, at the time of pressure regulation, the valve assembly 26 and the diaphragm assembly 38 are combined to move synchronously. At this time, when the vibration is applied to them in the compressed air, the dynamic vibration absorber 50 to the vibration control target consisting of the mass (M1 + M2) fixed to the spring member of the spring constant (K1 + K2) as shown in Figure 3a It is a vibration model of the complex vibration system attached. Since the complex natural frequency Ωc at this time is different from the natural frequency ω of the dynamic vibration absorber 50, the vibrations of the valve assembly 26 and the diaphragm assembly 38 are quickly suppressed by the dynamic vibration absorber 50. Thereby, the opening degree of the valve element 21 is prevented from deviating largely from the predetermined opening degree corresponding to the pressure of the pressure regulation chamber 32, and it is possible to stabilize the pressure of the secondary side port 16 to a set pressure at high precision. Do.

On the other hand, as shown in FIG. 2B, upon exhaust, the pressure regulation diaphragm 27 moves away from the stem 46. At this time, when vibration is applied to the diaphragm assembly 38 in the compressed air exhausted, the dynamic vibration absorber 50 is applied to the vibration control object made of a mass body M1 fixed to the spring member of the spring constant K1 as shown in FIG. 3B. It is a vibration model of the attached diaphragm vibration system. Since the natural frequency Ω 1 of the diaphragm vibration system is different from the natural frequency ω of the dynamic vibration absorber 50, the vibration of the diaphragm assembly 38 is quickly suppressed by the dynamic vibration absorber 50. As a result, vibration noise does not occur in the diaphragm assembly 38, and the air in the secondary port 16 is discharged to the outside.

In this way, since the dynamic vibration absorber 50 is attached to the spring chamber 31 of the pressure regulating diaphragm 27 of the pressure regulator, the pressure is not affected by opening and closing of the valve seat 18 and the relief ball 37. In adjustment, vibration of the valve assembly 26 together with the diaphragm assembly 38 is quickly suppressed, and in exhaust, vibration of the diaphragm assembly 38 is quickly suppressed. As a result, the resonance phenomenon of the valve element 21 is prevented at the time of pressure regulation, the resonance phenomenon of the pressure regulating diaphragm 27 is prevented at the time of exhaust, and the air supplied to the secondary port 16 is prevented. It is possible to set the pressure with high precision. Moreover, since the occurrence of each resonance phenomenon is prevented, it becomes possible to suppress wear of the O-ring 48 and deterioration of the pressure regulating diaphragm 27 to improve durability of the pressure regulator.

4 is a sectional view showing a pressure regulator of another embodiment according to the present invention. In the pressure regulator shown in FIG. 1, a seal member 24 is attached to the shaft portion 21a of the valve element 21 to support the valve element 21 in its axial direction and to be movable. An o-ring 48 is attached to the tip of 46 to axially contact and support the stem 46 in its axial direction. On the other hand, in the pressure regulator shown in FIG. 4, the pressure balance diaphragm 55 is provided in the guide hole 22 of the cap 13, which constitutes the housing 11 and in which the valve element 21 is assembled. . By this diaphragm 55, the valve element 21 is supported by the housing 11 so as to be movable forward and backward in the axial direction thereof. In addition, at the distal end of the stem 46, the stem 46 is movably supported in the opening and closing direction of the relief ball 37, while the communication between the secondary port 16 and the pressure control chamber 32 is blocked to seal the diamond. Fram 56 is installed. As a result, since the valve element 21 and the stem 46 do not move in contact with the housing 11, the guide for securing the lubricity of the valve element 21 and the stem 46 as shown in FIG. 1. It is not necessary to apply lubricating oil between the ball 22 and the seal member 24 and between the through hole 47 and the O-ring 48, and the lubricating oil is mixed in the compressed air flowing through the pressure regulator. none. Thus, the pressure regulator shown in FIG. 4 can also be used for pneumatic actuators of the oil forbidden specification which need to prevent the incorporation of oil into the air. In this way, even in the pressure regulator corresponding to the non-oil-pneumatic actuator, the dynamic vibration absorber 50 is attached to the spring chamber 31 side of the pressure regulating diaphragm 27 to obtain the same effect as the above-described embodiment. have.

On the other hand, in another embodiment, the cap 13 is formed integrally with the cap 13 and the flange-shaped mounting portion 13a fixed to the housing main body 12 by fastening members such as screws. ) Is provided with a guide cylinder portion 13b. The valve spring 25 is attached to the end of the valve element 21 shaft portion 21a and is disposed inside the guide ball 22.

The retainer 36 also includes a disk portion 36a abutting the pressure regulating diaphragm 27 and a supporting rod portion 36b penetrating the radially central portion of the pressure regulating diaphragm 27. A relief ball 37 is formed in the shaft center of the support rod portion 36b. When the hemispherical tip surface 49 of the stem 46 contacts the support rod portion 36b, the relief ball 37 is closed and the support is supported. The relief ball 37 opens when the rod portion 36b falls off the stem 46. A pressure regulating spring 43 and a coil spring 51 are mounted to the disk portion 36a through the spring receiving members 57 and 58, and an operation handle 44 for adjusting the amount of expansion and contraction of the pressure regulating spring 43 is provided. The lock cover 45 is not provided.

The present invention is not limited to the above-described embodiment, and various changes can be made without departing from the gist of the present invention. For example, as a structure for attaching the dynamic vibration absorber 50 to the pressure regulating diaphragm 27, the mass body by the spring member and the damping member may be attached to the pressure regulating diaphragm 27 so as to be movable. Of course, this is not limited to the above embodiment.

The pressure regulator is used in a pneumatic circuit for regulating the compressed air supplied from the compressor to a predetermined set pressure and supplying it to a pneumatic actuator such as a pneumatic cylinder.

11: housing
12: housing body
13: cap
14: Bonnet
15: Primary port
16: secondary port
17: communication hole
18: valve seat
21: valve element
22: guide ball
23: seal member
24: seal member for pressure balance
25: valve spring
26: valve assembly
27: pressure adjusting diaphragm
28: reinforcing disc
31: spring seal
32: pressure regulating chamber
42: spring handing member
43: pressure regulating spring
46: stem
50: dynamic vibration absorber

Claims (8)

A housing having a primary side port through which the pressure fluid is supplied and a secondary side port communicating with the primary side port through a communication hole and outflowing the pressure fluid;
A valve assembly having a valve element for opening and closing a valve seat formed at an opening end side of the communication hole, and a valve spring for applying a spring force to the valve element in a direction of closing the valve seat;
A pressure regulation diaphragm which is mounted in the housing opposite the valve element and defines a pressure regulation chamber in communication with the secondary port and a spring chamber in communication with the outside, and is disposed in the spring chamber opposite the retainer and the retainer installed in the pressure regulation diaphragm A diaphragm assembly having a pressure regulating spring mounted between the spring receiving member and applying a spring force to the valve element in a direction of opening the valve element at the valve seat;
A stem which is formed in the retainer and has a front end surface for opening and closing a relief ball communicating with the pressure regulating chamber and the spring chamber, imparting a spring force of the pressure regulating spring to the valve element, and forming a valve assembly;
It is attached to the retainer and placed in the spring chamber, and it suppresses the vibration of the diaphragm assembly when the diaphragm is away from the stem, and the diaphragm when the valve assembly adjusts the pressure of the secondary port while opening and closing the valve seat with the diaphragm assembly. And a dynamic vibration absorber to suppress vibration of the assembly and the valve assembly.
2. The dynamic vibration absorber according to claim 1, wherein the dynamic vibration absorber is mounted between an annular damper fixed to the tip of a supporting rod protruding from the retainer toward the spring receiving member, an annular mass installed on the annular damper, and between the diaphragm and the annular mass. And a spring member.
3. The retainer according to claim 2, wherein the retainer has a disk portion provided with a supporting rod and abuts on the diaphragm, and a dynamic vibration absorber is positioned at the tip of the supporting rod inside the pressure regulating spring mounted between the disk portion and the spring receiving member. And a pressure regulator.
The composite vibration system according to any one of claims 1 to 3, wherein the natural frequency of the dynamic vibration absorber comprises a natural frequency of the diaphragm vibration system constituted by a diaphragm assembly and a valve assembly and a diaphragm assembly. Pressure regulator characterized in that different from the natural frequency.
The seal member according to any one of claims 1 to 4, wherein the seal member seals the communication between the pressure control chamber and the secondary port communicating through a through hole that slidably supports the leading end of the stem. Pressure regulator, characterized in that installed in the tip of the stem.
The diaphragm according to any one of claims 1 to 4, wherein a diaphragm for movably supporting the stem in the opening and closing direction of the relief ball and sealing the communication between the secondary port and the pressure regulating chamber is provided at the tip of the stem. Pressure regulator, characterized in that.
7. The pressure regulator as claimed in any one of claims 1 to 6, further comprising a seal member for pressure balance which seals between the valve element and the guide ball in which the valve element is assembled.
The pressure regulator as claimed in claim 1, further comprising a diaphragm for pressure balancing sealing between the valve element and the guide ball in which the valve element is assembled.

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